Image forming apparatus

ABSTRACT

In an image forming apparatus according to the present invention, the force of a tension spring returning to its original position is utilized to vibrate or impact a conductive member using a predetermined timing, one end of the conductive member being fixed and the other end of the conductive member being connected to a knob via a tension spring. This serves to remove attachments adhering to the tips of the conductive member.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims the benefit of priority fromprior Japanese Patent Application No. 2003-393059, filed Nov. 21, 2003,the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to, for example, an image formingapparatus comprising an image reading device that obtains image datafrom a copy target.

2. Description of the Related Art

An image forming apparatus comprises a photosensitive member on which anelectrostatic image and a developer image are formed and a chargingdevice that charges the photosensitive member to a predeterminedpotential.

Known charging devices use a wire-, brush-, or needle-like electrode.

For example, Jpn. Pat. Appln. KOKAI Publication No. 2000-242060(Abstract, claim 1, FIG. 1, paragraphs [0024], [0025], and others)discloses a technique employing a charging device having a wire-likeelectrode. With this technique, a piezoelectric transformer is connectedto the wire-like electrode so as to supply a high-voltage to thewire-like electrode. Then, the wire is prevented from being contaminatedby transmitting to the wire a mechanical vibration which generated whenthe piezoelectric transformer is driven.

Further, Jpn. Pat. Appln. KOKAI Publication No. 2002-123068 (Abstract,claim 1, FIG. 1, paragraphs [0006], [0007], and others) discloses atechnique employing a charging device having a brush-roller-likeelectrode. With this technique, vibration is generated in an axialdirection to cause attachments adhering to an outer peripheral surfaceof the brush roller to float. Then, sucking means is used to collect theattachments.

Moreover, Jpn. Pat. Appln. KOKAI Publication No. 5-107867 (Abstract,claim 1, FIG. 1, paragraphs [0024], [0025], and others) discloses atechnique also employing a charging device having a brush-roller-likeelectrode. With this technique, vibration is generated in the axialdirection to prevent non-contact between the brush roller and aphotosensitive drum in the axial direction. The photosensitive drum isthus charged to a uniform potential.

Furthermore, Jpn. Pat. Appln. KOKAI Publication No. 2000-58224(Abstract, claim 1, FIG. 3, and others) discloses a technique employinga charging device having a saw-tooth-like electrode. With thistechnique, a cleaning member is abutted against the saw-tooth-likeelectrode. The cleaning member then moves parallel to the electrode toremove contamination from the electrode.

As described above, when attachments adhere to a charging devicecharging a photosensitive member, disadvantageously the entirephotosensitive member is not uniformly charged. In particular, if aneedle-like electrode such as the one shown in Patent Document 4 isused, when a developer or attachment such as dust which floats through amain body adheres to the needle-like electrode, an insufficientdischarge may occur in the adhering parts. Thus, a nonuniform dischargemay occur on the surface of the photosensitive member; that is, anonuniform potential may be formed in the axial direction. This mayprevent a satisfactory image from being formed.

Further, with the technique disclosed in Patent Document 4, the cleaningmember is brought into contact with the needle of the electrode.Consequently, the needle may be bent by the cleaning member caught atthe tip of the needle. On this occasion, the bent needle cannot cause asufficient discharge, resulting in a nonuniform discharge from thesurface of the photosensitive member. This may prevent a satisfactoryimage from being formed.

BRIEF SUMMARY OF THE INVENTION

Additional objects and advantages of the invention will be set forth inthe description which follows, and in part will be obvious from thedescription, or may be learned by practice of the invention. The objectsand advantages of the invention may be realized and obtained by means ofthe instrumentalities and combinations particularly pointed outhereinafter.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

The accompanying drawings, which are incorporated in and constitute apart of the specification, illustrate embodiments of the invention, andtogether with the general description given above and the detaileddescription of the embodiments given below, serve to explain theprinciples of the invention.

FIG. 1 is a schematic diagram illustrating an example of an imageforming apparatus according to the present invention;

FIG. 2 is a schematic diagram of a charging device illustrating a firstembodiment;

FIG. 3 is a schematic diagram showing a conductive member;

FIG. 4 is a schematic diagram showing attachments adhering to theconductive member;

FIG. 5 is a schematic diagram illustrating an attachment removingmechanism shown in FIG. 2;

FIG. 6 is a schematic diagram illustrating the attachment removingmechanism shown in FIG. 2;

FIG. 7 is a schematic diagram of a charging device illustrating a secondembodiment;

FIG. 8 is a block diagram showing how to control the charging device ofthe image forming apparatus according to the present invention;

FIG. 9 is a flowchart illustrating an example of a method for operatingthe attachment removing mechanism;

FIG. 10 is a schematic diagram illustrating a third embodiment; and

FIG. 11 is a schematic diagram illustrating a fourth embodiment.

DETAILED DESCRIPTION OF THE INVENTION

With reference to the drawings, description will be given of an exampleof an image forming apparatus according to the present invention.

As shown in FIG. 1, an image forming apparatus 1 comprises a scanner(image reading device) 100 that reads an image from a read target (copytarget) to generate a first image signal, and an image forming section120 that forms an image on the basis of a second image signal. Thescanner 100 may be provided with an automatic document feeding device(ADF) 140.

The scanner 100 comprises a document table 101, an illuminating lamp103, a reflector 104, a first carriage 105, a first mirror 106, a secondcarriage 107, a second mirror 108, a third mirror 109, a lens 110, aphotoelectric converting element (CCD sensor) 102, and an imageprocessing section 111.

The document table 101 consists of a light-transmissive material andholds a copy target (document) P that is a three-dimensional object suchas a book or a sheet-like document.

The illuminating lamp 103 irradiates the document table 101 with lightfrom below.

The reflector 104 condenses and directs light emitted by theilluminating lamp 103 to a predetermined position on the document table101.

The illuminating lamp 103 and the reflector 104 are fixed to the firstcarriage 105. The first carriage 105 reciprocates along a surface of thedocument table 101.

The first mirror 106 guides a reflected light from the document Pilluminated by an illumination light from the illuminating lamp 103 andreflector 104, that is, image information from the document P, in apredetermined direction (to the second carriage 107). For description,the reflected light from the document will hereinafter be referred to asimage light.

The second carriage 107 holds and moves the second mirror 108 and thirdmirror 109 along the surface of the document table 101 in unison withthe first carriage 105.

The second mirror 108 bends image light reflected by the first mirror106 through 90° and then guides the bent light to the third mirror 109.

The third mirror 109 bends the image light reflected by the secondmirror 108 through 90° and then guides the bent light to the lens 110.

The lens 110 provides the guided image light with a predetermined imageformation magnification. The lens 110 forms an image on the CCD sensor102, placed at a focal position of the lens 110.

The CCD sensor 102 converts the image information (image light) from thedocument P into an electric signal. The CCD sensor 102 then outputs afirst image signal.

The image processing section 111 executes a predetermined image processon the first image signal outputted by the CCD sensor 102. The imageprocessing section 111 outputs image information as a second imagesignal.

The image forming section 120 comprises a charging device 121, anexposure device 122, a photosensitive drum 123, a developing device 124,a sheet cassette 125, a pickup roller 126, a conveying path 127, analigning roller 128, a transfer device 129, a fixing device 130, a paperdischarging roller 131, a tray 132, and a cleaning mechanism 133.

The charging device 121 causes a discharge at a predetermined dischargeposition to supply predetermined charges to an outer peripheral surfaceof the photosensitive drum 123.

The exposure device 122 outputs a laser beam having a light intensityvaried on the basis of a second image signal output by the imageprocessing section 111. The laser beam is incident on the outerperipheral surface of the photosensitive drum 123 charged by thecharging device 121 to a uniform potential in an axial direction.

The photosensitive drum 123 is irradiated with a laser beam and holds anelectrostatic image, that is, an electrostatic latent image,corresponding to the image from the document P.

The developing device 124 provides a developer (for example, a toner) tothe photosensitive drum 123 rotating in the direction of an arrow A. Theelectrostatic latent image (not shown) is converted into a toner image.

The sheet cassette 125 accommodates paper Q.

The pickup roller 126 takes the paper Q out of the sheet cassette 125sheet by sheet to guide it to the conveying path 127.

The conveying path 127 has a plurality of rollers to guide the paper Qto the photosensitive drum 123.

The aligning roller 128 stops the paper Q guided through the conveyingpath 127 in order to align the toner image (not shown) with a positionon the paper Q to which the toner image is to be transferred. Thealigning roller 128 then conveys the paper Q to the photosensitivemember 123 at a predetermined time.

The transfer device 129 electrostatically transfers the toner image tothe paper Q at a transfer position opposite the photosensitive drum 123,that is, at a predetermined downstream position in a direction in whichthe developing device 124 is rotated.

The fixing device 130 secures or fixes the toner image (not shown)transferred to the paper Q, to the paper Q.

The paper discharging roller 131 discharges the paper Q to which thetoner image (not shown) has been fixed by the fixing device 130, thatis, the paper Q on which the image corresponding to the imageinformation from the document P has been formed, into an image outputmedium holding section (tray) 132.

The tray 132 is located in a space defined between the scanner 100 andthe sheet cassette 124.

The cleaning mechanism 133 is located downstream of the transferposition and upstream of the discharge position in the direction inwhich the photosensitive drum 123 is rotated. The cleaning mechanism 133removes a toner remaining without being transferred, from the surface ofthe photosensitive drum 123.

The image forming section 120 is provided with the charging device 121,the photosensitive drum 123, the developing device 124, and the cleaningmechanism 133 as a single unit (process unit).

When an instruction to read an image from the document P or to form animage is given, the scanner 100 outputs a first image signal based onthe document P to the image processing section 111. The image processingsection 111 outputs a second image signal to the exposure device 122.The exposure device 122 irradiates the photosensitive drum 123 with alaser beam to form an electrostatic image. The developing device 124converts the electrostatic image into a toner image. The transfer device129 transfers the toner image to the paper Q. The fixing device 130fixes the toner to the paper Q, that is, forms the image from thedocument P on the paper Q.

First Embodiment

FIG. 2 is a schematic diagram showing an example of the charging device121, shown in FIG. 1.

As shown in FIG. 2, the charging device 121 comprises a charger section200, a charger case section 210, and an attachment removing mechanism220. The charging device 121 is fixed to a process unit case (not shown)accommodating the process unit so that the rear of the image formingapparatus 1 lies on the right of the sheet showing FIG. 2, while itsfront lies on the left of the sheet. A closable door is provided in thefront of the image forming apparatus 1. A user can perform predeterminedoperations through the door.

The charge section 200 includes a conductive member 201, a plate spring202, and feeding section 203.

The conductive member 201 consists of stainless steel or the like havinga predetermined length in the axial direction of the photosensitive drum123. The conductive member 201 has a plurality of charging needles 201 asuch as those shown in FIG. 3; the charging needles 201 a are providedon one side of the conductive member 201. Further, as shown in FIG. 2, ahole 201 b supported by the attachment removing mechanism 220 is formedat the front end of the conductive member 201. A hole 201 c to where theplate spring 202 is fixed is formed at the rear end.

The plate spring 202 is electrically connected to the hole 201 c in theconductive member 201 at one end. The plate spring 202 is fixed to thefeeding section 203 at the other end.

The feeding section 203 is fixed to, for example, a predetermined rearposition of the process unit case (not shown). The feeding section 203is electrically connected to a high-voltage generating mechanism 411(see FIG. 8), described later.

The charger section 200 is fixed to the process unit case so that theaxes of the conductive member 201 and photosensitive drum 123 areparallel to each other; this arrangement makes it possible to ensure aspecified distance between the plurality of charging needles 201 a andthe photosensitive drum 123 in the axial direction.

The charger case section 210 includes a center case 211, a firstterminal case 212, and a second terminal case 213.

The center case 211 consists of a heat insulating member, for example,metal and surrounds the conductive member 201 except for its surfacethrough which the charging needles 201 a lie opposite the photosensitivedrum 123, the surface being closer to the bottom of the sheet of thedrawing. This inhibits dust, paper dust, toner, and the like(attachment) form flowing through the main body from beingelectrostatically attracted to the conductive member 201, particularlyits tip 201 d.

The first and second terminal cases 212 and 213 consist of, for example,an insulating material such as resin. The first and second terminalcases 212 and 213 hold the center case 211 and are fixed in theapparatus, for example, to the process unit case.

The second terminal case 213 has a case hook portion 213 a on its sideopposite to that to which the center case 211 is fixed, that is, on itsfront.

The attachment removing mechanism 220 includes a tension spring 221 anda knob 222.

The tension spring 221 is an elastic member consisting of, for example,a spring which is formed by spirally winding an electric wire having apredetermined rigidity and which has key-like catching portions formedat its opposite ends. One end of the tension spring 221 engages with thehole 201 b in the conductive member 201. The other end engages with theknob 222.

The knob 222 has a hook portion 222 a engages with the case hook portion213 a. The knob 222 is located by the case hook portion 213 a at a firstposition (fixture reference). The knob 222 thus maintains a tensionapplied by the tension spring 221 to the conductive member 201 at leasta specified value, that is, so as to prevent the conductive member 201from slackening. Further, the knob 222 is provided so as to be movablefrontward at least from a first position to a second position, that is,a distance corresponding to a displacement D1.

The tension spring 221 applies at least a specified tension to theconductive member 201, which can thus maintain a rectilinear shapeparallel to the axis of the photosensitive drum 123. However, of course,the conductive member 201 may further have a support member with apredetermined hardness, for example, at a position where the supportmember does not interfere with discharge from the charging needles 201a, for example, on the side closer to the top of the sheet of thedrawing, which is opposite the side closer to the bottom of the sheet onwhich the charging needles 201 a are formed.

When the image forming apparatus 1 is instructed to read or form animage, the feeding section 203 supplies predetermined power. Theconductive member 201 starts discharging from the plurality of chargingneedles 201 a (for example, corona discharge) to provide predeterminedcharge to the photosensitive drum 123. As more and more images areformed, dust, paper dust, toner, and the like (attachment F) driftingthrough the main body is electrostatically attracted to the tips 201 d(at which discharge occurs) of the charging needles 201 a. Theattachment adheres to the tips 201 d like fluff as shown in FIG. 4.

The attachment F is attached by a very weak force to the tips 201 d.Accordingly, the attachment F is shaken off by a weak vibration orimpact which is caused when, for example, the process unit is installedor removed.

The attachment F is preferably removed when a defective image is outputbecause of a nonuniform discharge or the like, for example, when theuser determines from the image formed that the attachment F adhering tothe conductive member 201 must be removed.

As shown in FIG. 5, the user pulls out the knob 222 frontward and thenreleases it. Then, the tension spring 221 exerts a force to return tothe original position, that is, the first position. The knob 222 is thusreturned to the first position as shown in FIG. 6.

At this time, the control hook portion 222 a collides against the casehook portion 213 a to vibrate the conductive member 201. Consequently,the attachment F adhering to the tips 201 d of the conductive member 201is shaken off.

Second Embodiment

FIG. 7 is a schematic diagram showing a different example of thecharging device 121, shown in FIG. 1.

As shown in FIG. 7, a charging device 300 comprises the charger section200, the charger case section 210, and an attachment removing mechanism310.

As described above, the charger section 200 includes the conductivemember 201, the plate spring 202, and the feeding section 203. Thecharger case section 210 includes the center case 211, the firstterminal case 212, and the second terminal case 213. Each of thesecomponents has a configuration similar to that in the description ofFIG. 2. Accordingly, detailed descriptions are omitted.

The attachment removing mechanism 310 includes the tension spring 221, acontrol 311, an arm 312, and an arm power section 313.

As described above, one end of the tension spring 221 engages with thehole 201 b in the conductive member 201. The other end engages with thecontrol 311.

The control 311 has a control hook portion 311 a engages with the casehook portion 213 a. The control 311 engages with the case hook portion213 a to sit at the first position. Then, the control 311 is movedfrontward the distance corresponding to the displacement D1 to sit atthe second position. In other words, the control 311 is provided so asto be movable from the first position to the second position.

The arm 312 includes a first arm member 312 b rotated around a fulcrum312 a and a second arm member 312 c formed at a predetermined angle tothe first arm member 312 b around the fulcrum 312 a. The first armmember 312 b is fixed to the control 311. The second arm member 312 c isfixed to the arm power section 313.

The arm power section 313 is, for example, a solenoid, and when suppliedwith predetermined power, moves the fixed second arm member 312 c in thevertical direction of the sheet of the drawings (the direction of arrowL), that is, the direction perpendicular to the axis of thephotosensitive drum 123. Correspondingly, the first arm 312 b swingsclockwise to move the control 311 toward the left end of the sheet ofthe drawing.

FIG. 8 is a block diagram illustrating a control system that operatesthe image forming apparatus including the charging device 300, shown inFIG. 7.

As shown in FIG. 8, a main CPU 410 is connected to a printer CPU 420 anda control panel 430.

The main CPU 410 integrally controls the components of the image formingapparatus 1.

The printer CPU 420 integrally controls the components of the imageforming section 120.

The control panel 430 comprises an operation section 431 to communicatean instruction from the user to the main CPU 410 or printer CPU 420.

When the user gives an instruction to form an image from the operationsection 431, the printer CPU 420 outputs a charging signal to cause theplurality of charging needles 201 a of the conductive member 201 tostart discharging.

On receiving the charging signal input by the printer CPU 420, the mainCPU 410 outputs a high-voltage generation signal.

Further, when an instruction to remove the attachment F is given, theprinter CPU 420 outputs a drive signal at a predetermined time to drivea driving circuit 424.

The main CPU 410 is connected to the high-voltage generating mechanism411 and a main motor 412.

The high-voltage generating mechanism 411 is connected to a power supplysection (not shown) that supplies power required to operate the imageforming apparatus 1. Predetermined power is thus supplied. On receivingthe high-voltage generation signal input by the main CPU 410, thehigh-voltage generating mechanism 411 generates high-voltage powerrequired to discharge electricity from the conductive member 201 inorder to charge the photosensitive drum 123 to a predeterminedpotential. The high-voltage generating mechanism 411 supplies the powerto the supply section 203, connected to the conductive member 201.

The main motor 412 operates the components of the scanner 100, imagereading section 120, and the like, for example, the first and secondcarriages 105 and 107 or the photosensitive drum 123.

The printer CPU 420 is connected to a ROM 421, a RAM 422, a counter 423,and the driving circuit 424.

The ROM 421 stores a program that integrally controls the components ofthe image forming section 120 and exclusive programs that controldischarge from the conductive member 201 or the arm power section.

The RAM 422 has, for example, a work area required by the printer CPU420 to perform predetermined processing operations.

The counter 423 counts the number of output media (paper Q) on whichimages have been formed using the image forming section 120. The counter423 reports the number to the printer CPU 420.

The driving circuit 424 receives the drive signal input by the printerCPU 420 to operate the connected arm power section 313.

Now, description will be given of a first method of shaking offattachment, that is, attachments adhering to the conductive member 201.

On receiving an instruction to form an image from the control panel 430,the printer CPU 420 outputs a charging signal. The charging signalcauses the main CPU 410 to output a high-voltage generation signal. Onreceiving the high-voltage generation signal, the high-voltagegenerating mechanism 411 provides high-voltage power to the supplysection 203. The supply section 203 transmits the high-voltage power tothe conductive member 201. The conductive member 201 then provides apredetermined charge to the photosensitive drum 123.

As more and more images are formed, dust, paper dust, toner, or the like(attachment) drifting through the main body is electrostaticallyattracted to the tips 201 d (at which discharge occurs) of the chargingneedles 201 a. The attachment adheres to the tips 201 d as contaminants.The attachment F or the like may then cause a nonuniform discharge.Thus, a defective image may be output.

Accordingly, for example, when the user determines that the attachment Fmust be removed because the defective image has been output and thengives, from the operation section 431, an instruction to remove theattachment, the printer CPU 420 outputs a drive signal to the drivingcircuit 424. The drive signal causes the driving circuit 424 to supplypredetermined power to the solenoid 313, serving as the arm powersection. That is, the solenoid 313 is energized. One end of thehigh-voltage generating mechanism moves in the direction of the arrow L,that is, in the direction orthogonal to the axis of the photosensitivedrum 123. This converts the power of the solenoid 313 so that the poweracts in the direction of an arrow M, that is, toward the photosensitivedrum 123. As a result, the control 311 is pulled forward.

When the solenoid 313 is deenergized, the tension spring 221 attempts toreturn to its original position to return the control 311 to the firstposition as shown in FIG. 7.

Once the control 311 is returned to the first position, the control hookportion 311 a collides against the case hook portion 213 a to vibratethe conductive member 201. This vibration shakes off the attachment Fadhering to the tips 201 d of the conductive member 201.

The time for which the driving circuit 424 supplies power is counted bythe counter 423 or may be such that the control 311 can apply vibrationto the conductive member 201 which is sufficient to shake off theattachment F.

The arm power section is not limited to the solenoid 313 but has only toprovide power to the control 311 in the direction of the arrow M.

Further, the method of outputting a drive signal is not limited to theabove aspect but a second method, for example, one shown in FIG. 9, maybe used.

FIG. 9 is a flowchart illustrating the second method of shaking off theattachment. In this case, the ROM 421 stores a program that allows theprinter CPU 420 to output a drive signal if the number of output mediaNQ1 counted by the counter 423 reaches a prespecified value NQ2 (forexample, 1,000) with which a defective image may be formed.

As shown in FIG. 9, the printer CPU 420 compares the number of outputmedia NQ1 counted by the counter 423 with the print specified value NQ2(S1).

If the number of output media NQ1 counted is at least 1,000 (S1-YES),the printer CPU 420 then monitors a motor drive signal for a motordriver circuit (not shown) to determine whether or not the main motor412 is operating (S2). If the main motor 412 is not operating (S2-NO),the printer CPU 420 outputs a drive signal (S3).

When the drive signal is input to the driving circuit 424, the solenoid313 is energized to cause vibration or an impact to shake off theattachment as described above.

While the main motor 412 is operating, one or both of the scanner 100and image reading section 120 are operating. Accordingly, if the imageforming section 120 is operating, that is, a toner image is being formedon the photosensitive drum 123, there is no possibility of theattachment F falling onto the surface of the photosensitive drum 123. Ifthe scanner 100 is operating, there is no possibility of vibrationgenerated by the arm power section 313 hinder a reading operation.

Third Embodiment

FIG. 10 is a schematic diagram showing a further different example ofthe charging device 121, shown in FIG. 1.

As shown in FIG. 10, a charging device 500 comprises the charger section200, a charger case section 510, and an attachment removing mechanism520.

The charger section 200 includes the conductive member 201, the platespring 202, and the feeding section 203. Each of these components has aconfiguration similar to that in the description of FIG. 2. Accordingly,their description is omitted.

The charger case section 510 includes a center case 511, the firstterminal case 212, and a second terminal case 512.

The center case 511 consists of a heat-insulating member, for example,metal, and surrounds the conductive member 201 except for its surfacethrough which the charging needles 201 a lie opposite the photosensitivedrum 123, the surface being closer to the bottom of the sheet of thedrawing. A pin portion 511 b having a pin 511 a is formed at one end ofa top surface portion of the center case 511, that is, the portion ofthe center case 511 located opposite the photosensitive drum 123. A pinportion 511 d having a pin 511 c is formed at the other end.

The first and second terminal cases 212 and 512 consist of, for example,an insulating material such as resin. The second terminal case 512 has aterminal hook 512 a at a predetermined position on which the tensionspring 221 can be engage.

One of compression springs 513 and 514 is fixed to the process unit case134, while the other compression spring 514 and 513 is fixed to thecenter case 511. These springs exert a predetermined pressure on thefirst and second terminal cases 212 and 512 toward the bottom of thesheet of the drawing, that is, toward the photosensitive drum 123. Theprocess unit case 134 supports the first and second terminal cases 212and 512, on which the predetermined pressure is exerted, in places wherethe first and second terminal cases 212 and 512 do not interfere withcharging of the photosensitive drum 123.

The attachment removing mechanism 520 includes a first cam 521 and asecond cam 522.

The first and second cams 521 and 522 are fixed to a rotating shaft onwhich, for example, a motor 530 connected to the printer CPU 420 exertsa rotating force acting in counterclockwise direction of the sheet ofthe drawing. Each of the first and second cams 521 and 522 is shapedlike, for example, an oval having a part with a long distance from therotating shaft and a part with a shorter distance from the rotatingshaft.

On receiving a drive signal input by the printer CPU 420, the motor 530rotates the rotating shaft a predetermined number of times (for example,once).

Description will be given of an operation of shaking off attachment,that is, attachments adhering to the conductive member 201, by applyingthe first method based on the instruction from the control panel 430 asdescribed above.

For example, when the user determines that the attachment must beremoved because a defective image has been output and then gives, fromthe operation section 431, an instruction to remove the attachment, theprinter CPU 420 outputs a drive signal to the motor 530. Then, the motor530 rotates the rotating shafts.

The first and second cams 521 and 522 rotate around the respectiverotating shafts and reach respective predetermined positions. Then, thefirst and second cams 521 and 522 abut against the respective pins 511 aand 511 c to lift the charger sections 200 and 510 via the pins 511 aand 511 c, respectively, in the upward direction of the sheet of thedrawing. A further rotation of the rotating shafts causes the first andsecond cams 521 and 522 to leave the pins 511 a and 511 b, respectively.The compression springs 513 and 514 then serve to locate the chargercase section 510 at its original position, that is, the position whereit is supported by the process unit case 134. The charger case section510 then collides against the process unit case 134. This causes theconductive member 201 to vibrate to shake off the attachment, that is,the attachments adhering to the conductive member 201.

As shown in the flow-chart in FIG. 9, if the number of output media NQ1has reached the specified value NQ2, which is fixed, and the main motor412 is not operating, then the printer CPU 420 outputs a drive signal.

When the drive signal is input to the motor 530, the first and secondcams 521 and 522 rotate to generate vibration or an impact, thus shakingoff the attachment adhering to the tips 201 d of the conductive member201 as described above.

Fourth Embodiment

FIG. 11 shows an example of an attachment removing mechanism differentfrom that according to the third embodiment shown in FIG. 10.

As shown in FIG. 11, a charging device 600 comprises the charger section200, the charger case section 510, and an attachment removing mechanism610.

The attachment removing mechanism 610 comprises an arm 611 and an armpower section 612.

The arm 611 has a predetermined distance sufficient to reach the pins511 a and 511 c and is fixed to the arm power section 612 at its center.

The arm power section 612 is, for example, a solenoid, and when suppliedwith predetermined power, moves the arm 611 in the vertical direction ofthe sheet of the drawings (the direction of arrow L), that is, thedirection perpendicular to the axis of the photosensitive drum 123.

As in the case of the second embodiment, the arm power section 612 isconnected to the driving circuit 424. When the printer CPU 420 inputs adrive signal to the driving circuit 424, the arm power section 612 issupplied with predetermined power and is turned on.

Description will be given of an operation of shaking off attachment,that is, attachments adhering to the conductive member 201, using thefirst method based on the instruction from the control panel 430 asdescribed above.

For example, when the user determines that the attachment must beremoved because a defective image has been output and then gives, fromthe operation section 431, an instruction to remove the attachment, theprinter CPU 420 outputs a drive signal to the driving circuit 424.

Then, the solenoid 612 is energized to lift the arm 611 in the upwarddirection of the sheet of the drawing. The pins 511 a and 511 c arecaught on the arm 611 to lift the charger case section 510 upward.

Deenergizing the solenoid 612 causes the compression springs 513 and 514to push the charger case section 510 downward. The charger case section510 is then located at a predetermined position where it is supported bythe process unit case 134. The charger case section 510 thus collidesagainst the process unit case 134. This causes the conductive member 201to vibrate to shake off the attachment F adhering to the tips 201 d ofthe conductive member.

Description will be given of an operation of shaking off attachment,that is, attachments adhering to the conductive member 201, by applyingthe second method based on the instruction from the counter 423 asdescribed above.

As shown in the flowchart in FIG. 9, if the number of output media NQ1has reached the specified value NQ2, which is fixed, and the main motor412 is not operating, then the printer CPU 420 outputs a drive signal.

When the drive signal is input to the driving circuit 424, the solenoidis energized and deenergized to generate vibration or an impact, thusshaking off the attachment F adhering to the tips 201 d of theconductive member, as described above.

1. An image forming apparatus comprising: a charging member including aconductive member having a plurality of projecting portions formed alongan axial direction of an image carrier so that a discharge occurs on theplurality of projecting portions to provide a predetermined potential tothe image carrier; a plate member electrically connected to one end ofthe charging member and fixed at a predetermined position; an elasticmember connected to the other end of the charging member to hold thecharging member using a predetermined tension; and a pullout memberconnected to the elastic member and provided so as to be movable betweena first position and a second position; wherein the elastic member isdisplaced as the pullout member moves, to vibrate or impact the chargingmember utilizing a force exerted to return to the first position.
 2. Theimage forming apparatus according to claim 1, wherein the pullout memberis connected to a power mechanism which provides the pullout member withpower required for the movement.
 3. The image forming apparatusaccording to claim 2, wherein the power mechanism comprises a motor. 4.The image forming apparatus according to claim 2, wherein the powermechanism comprises a solenoid.
 5. The image forming apparatus accordingto claim 2, wherein the power mechanism is accessed by operating acontrol panel.
 6. An image forming apparatus comprising: a chargingmechanism which includes an electrode to provide a predeterminedpotential for an image carrier; an elastic member which holds theelectrode at a predetermined position using a predetermined tension; anattachment removing mechanism which generates vibration or impactutilizing a force of the electrode undergoing a predetermineddisplacement and returns to an original position, the attachmentremoving mechanism shaking off attachments electrostatically adhering tothe electrode; counting means for counting the number of output media onwhich images have been formed; control means for operating theattachment removing mechanism if the number of output media counted bythe counting means reaches a prestored specified value; a plate memberelectrically connected to one end of the charging mechanism and fixed ata predetermined position; and a pullout member connected to the elasticmechanism connected to the other end of the electrode, and provided soas to be movable between a first position and a second position, whereinthe elastic member is displaced as the pullout member moves, to vibrateor impact the electrode utilizing a force exerted to return to the firstposition.
 7. The image forming apparatus according to claim 6, furthercomprising: a case which supports the charging mechanism placed at theoriginal position by the tension of the elastic member, wherein theelastic member includes compression springs.
 8. The image formingapparatus according to claim 6, wherein the electrode has a plurality ofprojecting portions formed along an axial direction of the image carrierso that the projecting portions are discharged to provide thepredetermined potential for the image carrier.